CN116157058A - Bone fixation monitoring system - Google Patents
Bone fixation monitoring system Download PDFInfo
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- CN116157058A CN116157058A CN202180060565.7A CN202180060565A CN116157058A CN 116157058 A CN116157058 A CN 116157058A CN 202180060565 A CN202180060565 A CN 202180060565A CN 116157058 A CN116157058 A CN 116157058A
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Abstract
The present invention provides a system for monitoring ossification of an internal fixation fracture in a bone of a subject comprising an implantable fixation device and an external wireless reader operable to transmit relative load data experienced by a bone plate across the fracture to a data server where the trend of the increased bone support provided by the bone plate can be visualized. The implantable fixture includes a primary load sensor and a reference load sensor, wherein a load value from the reference load sensor is operable to normalize the load value from the primary load sensor. The external wireless reader is in wireless communication with the implantable fixture and is operable to receive signals indicative of a load from each load sensor and energize each load sensor via inductive charging.
Description
Cross Reference to Related Applications
The present application claims priority from U.S. provisional patent No. 63/054,557, filed 7/21/2020, which is incorporated by reference in its entirety.
Technical Field
The present disclosure relates generally to systems and methods for monitoring healing/ossification of fractured bones.
Background
Conventional bone fixation systems include a bone plate having screw holes that receive a fixation member, such as a screw, that is configured to attach to an underlying bone that includes at least a pair of bone segments separated by a bone gap. The bone gap may be a fracture formed by a traumatic event, an osteotomy, or may be the result of joint debridement of two discrete bones to be joined in an arthrodesis. Thus, bone plates may be attached to bone on opposite sides of a bone gap via bone screws to promote union of bone segments (e.g., healing of a fracture or ossification of a joint). The bone fixation system may also include temporary kirschner-wires (temporary Kirschner wires) (K-wires) that are temporarily inserted into holes of the bone fixation plate and into the underlying bone segments to determine the proper length, rotation, and alignment of the bone segments prior to fixation of the permanent plate. Once the bone fixation plate has been properly positioned, permanent bone screws may be inserted into one or more bone screw holes on opposite sides of the bone gap and attached to the underlying bone.
Disclosure of Invention
A system for monitoring ossification of an internal fixation fracture in a bone of a subject includes an implantable fixation device and an external wireless reader. The external wireless reader is operable to transmit the relative load data experienced by the bone plate across the fracture to a data server where the trend of the increased bone support provided by the bone plate can be visualized.
The implantable fixation device includes a primary load sensor and a reference load sensor, each in direct physical contact with the bone plate. The primary load sensor is disposed at a first location on the bone plate that is operable to be positioned directly adjacent the fracture. The primary load sensor may generally include: a first strain sensor operable to monitor an amount of strain (primary strain) at a first location of the bone plate; and communication circuitry operable to transmit a first wireless signal indicative of the amount of primary strain. The reference load sensor is disposed on the bone plate at a second location spaced apart from the first location. The reference load sensor may include a second strain sensor operable to monitor an amount of strain (reference strain) at a second location in the bone plate; and communication circuitry operable to transmit a second wireless signal indicative of the reference strain amount.
The external wireless reader may receive the first wireless signal and the second wireless signal via the antenna, determine a relative amount of support provided by the bone plate due to the fracture using the received indication of the primary strain and the received indication of the reference strain, and transmit the determined relative amount of support to the data server over a wireless communication network using the wireless communication radio. In one configuration, the relative amount of support provided by the bone plate due to the fracture may be calculated by dividing the primary strain value by the reference strain value.
Using these devices, a method of acquiring ossification data of bone from an implantable intelligent fixation device disposed within a subject may begin by: an external antenna provided with an external wireless reader is energized to generate an alternating magnetic field and each of the main load sensor and the reference load sensor is inductively energized. The external wireless reader may then receive wireless data signals from each load sensor that are indicative of the amount of strain experienced by the bone plate at the respective location.
Furthermore, a method of monitoring fracture ossification from a plurality of subjects via a data server may begin by: a plurality of ossified data points from a plurality of subjects is received via a wireless communications network. Each data point represents a measurement taken from a smart fixture fixed to the subject's bone across the fracture. The measurement represents the amount of load carried by the fixation device across the fracture relative to the amount of load carried by the fixation device at the dense bone. The method further includes storing each of the plurality of data points in the non-volatile memory in combination with a date and time the measurement was taken and with a patient identifier representing a source of the measurement. The data server may then provide a physician interface to graphically illustrate the change in measurement results from each of the plurality of different subjects over time.
In one configuration, the data server may maintain a machine learning predictive model that generates a predicted patient-specific healing trajectory for each subject. The patient-specific healing trajectory comprises a predicted trajectory and a confidence interval representing a possible healing progression that starts at the time of bone fixation. The method further includes overlaying a plurality of data points or empirical trend lines of the subject on the graphical representation of the predicted patient-specific healing trajectory within the physician interface. The machine learning predictive model is improved using at least a subset of the received plurality of data points and a plurality of secondary factors including at least two of: the nature and location of the fracture, the subject's height, weight, age, sex, metabolic characteristics, blood pressure, past conditions, complex risk factors or complications.
The data server may also calculate a prospective healing trajectory for each subject that extends forward in time from the most recently acquired data points for that subject. The prospective healing trajectory may also be superimposed on a graphical representation of the predicted patient-specific healing trajectory. If one of the data point or the prospective healing trajectory is outside of the confidence interval, the data server may provide an alert via the physician interface.
As used herein, the terms "a," an, "" the, "" at least one, "" and "one or more" are used interchangeably to indicate that at least one of the items is present, and unless the context clearly dictates otherwise, there may be a plurality of such items.
Drawings
Fig. 1 is a schematic diagram of a system for monitoring fracture healing.
Fig. 2 is a schematic view of an implantable intelligent fixation device for surgically repairing fractured bones.
Fig. 3 is a schematic side perspective view of an external wireless reader for wireless connection with an implanted smart fixture.
Fig. 4 is a schematic diagram of a portable computing device in wireless communication with an implanted smart fixture via an external antenna.
Fig. 5 is a schematic illustration of the progression of a user interface display screen that may be displayed to a patient during a measurement via a portable computing device such as that shown in fig. 3-4.
Fig. 6 is a schematic diagram of a method of collecting and aggregating patient healing data from an implantable intelligent fixation device.
FIG. 7 is a schematic of a patient-specific trend line plotted by a plurality of load ratio data points acquired over time.
FIG. 8 is a schematic diagram of a physician interface that may display patient-specific healing trend lines constructed for one or more patients.
Fig. 9 is a schematic side perspective view of an external wireless reader secured to the upper thigh of a patient.
Detailed Description
The present technology relates generally to a system and device that enables a physician to better understand the healing and healing process of an internally immobilized fracture than more traditional forms of treatment. More specifically, the present design provides for periodic (even daily) testing of fracture healing progression while providing for the convenience of performing the test outside the confines of a clinic or examination room. By using connected hardware and a centralized data management system, the orthopedics physician can gain remote access to diagnostic data obtained directly from the internal fixation system. Using this quantitative data, the physician may be better prepared to provide consultation with the patient, for example in a virtual telemedicine-based manner. In this way, the present technology may make remote monitoring a required standard of care for monitoring the healing progress of an internally immobilized fracture.
Referring to the drawings, wherein like reference numbers are used to identify like or identical components throughout the several views, fig. 1 schematically illustrates a system 10 for remotely monitoring ossification/healing of a fracture or other bone joint that is internally fixed (as better shown in fig. 2) using a bone plate 12 and a plurality of permanent fixation members, such as bone screws 14. Generally, the present system 10 includes a data server 20 and/or a cloud computing system 22 operable to receive patient data 24 from one or more patient monitoring systems 26 over a wireless communication network 28. The data server 20/cloud computing system 22 may store the received patient data 24 in an associated non-volatile memory/database 30 and may visually present the data to a medical professional 32 via a hosted physician interface 34. Patient monitoring system 26 may be configured to periodically monitor the amount of load carried across the fracture by bone plate 12 during the entire healing process. The load measurements may be normalized to the load carried by the bone plate 12 away from the fracture and may be periodically transmitted from the patient monitoring system 26 to the data server 20 where they are aggregated with other patient data 24 to highlight the tendency of the fracture to heal.
With continued reference to FIG. 1, the data server 20 may be implemented as one or more high-speed server computers or mainframe computing devices capable of handling bulk data processing and data visualization tasks. On the other hand, the cloud computing system 22 may operate as middleware for IoT (internet of things), woT (internet of things), and/or M2M (machine-to-machine) services, connecting a wide variety of heterogeneous electronic devices with a Service Oriented Architecture (SOA) via a data network. As an example, cloud computing system 22 may be implemented as a middleware node to provide different functions for dynamically loading heterogeneous devices, multiplexing data from each of these devices, and routing the data through reconfigurable processing logic for processing and transmission to one or more target applications. The wireless communication network 28 may be any available type of network including a combination of public distributed computing networks (e.g., the Internet) and secure private networks (e.g., local area networks, wide area networks, virtual private networks). It may also include wireless and wireline transmission systems (e.g., satellite, cellular, terrestrial, etc.). Most, if not all, of the data transaction functions may be conducted, for example, over a wireless network, such as a Wireless Local Area Network (WLAN) or a cellular data network operating, for example, in accordance with the 4G, 5G, LTE, LPWAN, LTE-M, CAT-M1, or NB-IoT protocols.
As further shown in fig. 1, the patient monitoring system 26 generally includes an implantable smart fixture 40 and an external (in vitro) wireless reader 42 for connection with the smart fixture 40. The external wireless reader 42 is configured to wirelessly receive data from the smart fixture 40 through the patient's skin, for example, via a Radio Frequency (RF) data communication device such as RFID or NFC. In at least some embodiments, the external wireless reader 42 may also be configured to wirelessly provide a power source to the smart fixture 40, which may enable the fixture 40 to operate without an internal battery.
Referring to fig. 2, the implantable intelligent fixation device 40 may include a rigid bone plate 12 configured to be secured across and to opposite sides of the fracture 50 using a plurality of permanent fixation members, such as bone screws 14. The bone plate 12 may be formed of any suitable implantable material such as, but not limited to, a metal (e.g., titanium alloy) or a polymer such as Polyetheretherketone (PEEK). While the present disclosure generally discusses the use of remote monitoring techniques in conjunction with bone plate fixation devices, the present techniques may also be used with other rigid fixation members, such as implantable rods, pedicle screws, intervertebral implants, and the like.
The smart fixture 40 may generally include at least one primary load sensor 52 operable to sense the load carried by the plate at the fracture 50. As the fracture heals/ossifies, the amount of load carried by the plate 12 at the fracture 50 should decrease (i.e., the load carrying capacity of the healed bone increases accordingly at the same time). In many embodiments, the smart fixation device may also include at least one reference load sensor 54 operable to sense the load carried by the plate 12 at a location spaced apart from the fracture. The reference load sensor 54 may generally be used as a baseline for the amount of load carried by the plate 12 adjacent healthy or unbroken bone.
In one configuration, each load sensor 52, 54 may include one or more strain gauges 60 having electrical characteristics that vary in a given manner with the amount of strain experienced by the strain gauge/plate at that location. Examples of suitable strain gauges include resistive strain gauges, capacitive strain gauges, piezoelectric materials, electroactive polymer materials, and the like. Each strain gauge 60 may remain in firm, rigid contact with the plate 12 such that the strain gauge is also subject to any bending or flexing of the plate. It is well known that strain is proportional to load, and thus measuring strain is one way to monitor the load carried by a panel.
With continued reference to fig. 2, the smart fixture 40 also includes a communication circuit 62 electrically coupled to each of the strain gauges 60, and an antenna 64 in communication with the communication circuit 62. The communication circuit 62 is configured to receive the measurement values from the strain gauge 60 and provide the measurement values to the antenna 64 in a form suitable for wireless transmission. The communication circuit 62 may include a wireless transmitter or transponder that receives the measurement values from the strain gauge 60 and prepares the measurement values for wireless transmission. For example, the communication circuitry 62 may include processing components such as (but not limited to) one or more of the following: (i) a memory configured to store the measurement values, (ii) a digital-to-analog converter configured to convert the measurement values to an analog format, (iii) a Radio Frequency (RF) modulator configured to modulate the measurement values, (iv) an error correction encoder configured to encode the measurement values, and other processing consistent with wireless technology employed by the system.
In one example, the communication circuit 62 may be configured as a passive Radio Frequency Identification (RFID) transponder. Alternatively, communication circuit 62 may be configured using any other wireless communication technology suitable for communicating through the skin, such as, but not limited to, battery-assisted passive RFID, active RFID, bluetooth, and Wi-Fi. The communication circuit 62 may also include a unique Identifier (ID) that may be used to distinguish each load sensor from other sensors. In one example, the unique ID may be an ID of an RFID tag. The antenna 64 is configured to convert electrical signals corresponding to the measurements from the communication circuit 62 into radio waves to wirelessly transmit the measurements through the patient's skin to the external wireless reader 42 located outside the patient's body.
As further shown in fig. 2, the smart fixture 40 may include a power device 66 configured to supply power to the strain gauge 60 and the communication circuit 62. In at least some examples, the power device 66 may include an energy harvesting device configured to capture energy from a suitable energy source separate from the smart fixture 40. For example, the energy source may be a radio wave transmitted from an external wireless reader 42. Alternatively, the power device 66 may capture energy from the patient's body itself or from another external source (such as a source external to the patient's body). More broadly, the energy source may include, but is not limited to, sensed kinetic energy, an electric field, a magnetic field, and the like. However, in a preferred embodiment, power device 40 does not include a typical electrochemical cell.
In one configuration, each load sensor 52, 54 may have its own dedicated communication circuit 62, antenna 64, and/or power device 66, which are local (i.e., as an integrated package) to the respective load sensor. In such a configuration, the primary load sensor 52 may transmit a first wireless signal indicative of the amount of strain monitored by the primary load sensor 52 (i.e., the primary strain value), while the reference load sensor 54 may simultaneously transmit a second wireless signal indicative of the amount of strain monitored by the reference load sensor 54 (i.e., the reference strain value). In other embodiments, the smart fixture 40 may have a common communication circuit 62, antenna 64, and/or power device 66 that may be shared across the device 40 (i.e., where each load sensor 52, 54 is in electrical communication with the shared communication circuit 62, antenna 64, and/or power device 66). Further embodiments and disclosures of the intelligent fixtures 40 are provided in US 2019/0038214, which is incorporated by reference in its entirety for all purposes.
As described above, the external wireless reader 42 is configured to wirelessly receive data from the smart fixture 40 through the patient's skin. To facilitate these communications, as generally shown in FIG. 3, the external wireless reader 42 generally includes one or more antennas 70, such as a Radio Frequency Identification (RFID) antenna, in communication with a portable computing device 72. The antenna 70 may be configured to attach directly to the outer surface of the patient's body or clothing. Such attachment may be facilitated through the use of one or more straps 73, harnesses, brackets, adhesive patches, elastic sleeves, hoops, and the like. In one particular embodiment, the antenna 70 may be disposed within a flexible fabric carrier 74, which may be particularly adapted to conform to the contours of a user's body. The antenna 70 may generally comprise a loop coil having a length adapted to extend parallel to the bone plate 12 and a width adapted to extend transverse to the bone plate 12 and/or circumferentially therearound. The length may control the amount of board with which the antenna may communicate, while the width may affect the depth of tissue through which the antenna receives reliable signals. In one configuration, the length of the antenna 70 is greater than the distance between the primary load sensor 52 and the reference load sensor 54. In another configuration, the length of the antenna 70 is at least 10% greater than the distance between the primary load sensor 52 and the reference load sensor 54. In one embodiment, the antenna 70 may have a length of between about 20cm and about 50cm, or between about 25cm and about 40 cm. Likewise, the antenna 70 may have a width of between about 12cm and about 20cm or between about 14cm and about 17 cm.
As shown in fig. 4, the portable computing device 72 may include a short-range communication circuit 76 and/or a power transfer circuit 78 in communication with the antenna 70. The short-range communication circuit 76 is operable to receive digital information from the smart fixture 40 via the antenna 70. In some embodiments, the short-range communication circuit 76 may include a digital receiver or transceiver, such as an RFID transceiver or a Near Field Communication (NFC) transceiver. In one configuration, the antenna 70 may be in operative communication with each of the load sensors 52, 54 simultaneously, for example, by using different data transmission frequencies or by using different digital identifiers provided with the strain data. The power transfer circuit 78 may include an inductive charging circuit operable to supply electromagnetic power (i.e., alternating magnetic field) via the antenna 70 to inductively power the smart fixture 40.
With continued reference to fig. 4, the portable computing device 72 may also include a processor 80, a wireless communication radio 82, and a user interface 84. The wireless communication radio 82 is operable to communicate with and through the wireless communication network 28 and may include a bluetooth or bluetooth low energy chipset, a Wi-Fi radio operable to digitally communicate using a communication protocol in accordance with IEEE 802.11, or a cellular radio operable to communicate in accordance with 4G, 5G, LTE, LPWAN, LTE-M, CAT-M1, NB-IoT protocols, or the like. In some implementations, the portable computing device 72 may also include a Subscriber Identity Module (SIM) card to facilitate communication over a cellular network.
The processor 80 may be embodied as one or more digital computers, data processing apparatus and/or Digital Signal Processors (DSPs), which may have one or more microcontrollers or Central Processing Units (CPUs), read Only Memory (ROM), random Access Memory (RAM), electrically Erasable Programmable Read Only Memory (EEPROM), a high-speed clock, analog to digital (a/D) circuitry, digital to analog (D/a) circuitry, input/output (I/O) circuitry, and/or signal conditioning and buffering electronics. The processor 80 is configured to implement or perform one or more electronic functions by executing software or firmware code stored in a non-volatile memory accessible by the processor 80. For example, the processor 80 may be capable of implementing code that reads one or more strain values from the smart fixture 40, selects an average or filtered representative strain value, communicates with a user via the user interface 84, and/or communicates via the wireless communication radio 82 over the wireless communication network 28.
The portable computing device 72 may communicate with the antenna 70 using a wired communication link or a wireless communication link. In one configuration, such as generally shown in fig. 3, the portable computing device 72 may be electrically coupled to the antenna 70 through the use of a wired tether 86. Such designs may have the benefit of providing a self-contained diagnostic device that relies on only a single power source. More specifically, in the absence of the wired tether 86, the antenna 70 would require a first power source to enable/power communication with both the sensor and the portable computing device 72, whereas the portable computing device 72 would require a second power source. Coupling the two elements reduces the need for the consumer to maintain sufficient battery power on two separate devices while also reducing device complexity. The wired tether 86 also enables the portable computing device 72 to be held in a convenient and accessible position during data acquisition without the need to view the screen in a stressed posture that would otherwise be out of the patient's view. In one configuration, the antenna portion of the device may also include a holster or other securing mechanism for attaching and securing the portable computing device 72 when not in use.
In another embodiment, the portable computing device 72 may communicate wirelessly with the antenna 70 using a suitable wireless protocol. For example, in one configuration, portable computing device 72 may be a smart phone or tablet device that communicates wirelessly with an antenna (and/or communication circuitry disposed thereon) using, for example, the Bluetooth protocol.
As further shown in fig. 4, the user interface 84 may include a visual display 88 (such as an LCD or OLED display), and one or more input devices 90 such as buttons or a touch screen digitizer. As generally shown in fig. 5, the display 88 is operable to provide one or more visual cues to the patient, such as indicating the start of a reading (at 92), verifying sensor alignment (at 94), indicating the pose of a reference measurement and the occurrence of a reference measurement (at 96), indicating the pose of a load bearing measurement and the occurrence of a load bearing measurement (at 98), and/or uploading measurement data to a data server/cloud via the wireless communication network 28 (at 100).
Fig. 6 schematically illustrates a method 110 of collecting and aggregating patient cure data using the present system 10. The method 110 begins at 112 with the antenna 70 being positioned in contact with or outwardly adjacent to a skin surface of a body. In some configurations, such as when using an RFID communication protocol, the antenna 70 may be positioned such that it is generally centered over/radially outward of the at least one implantable primary load sensor 52 and the at least one implantable reference load sensor 54, with each load sensor 52, 54 in direct physical communication with the bone plate 12 or other bone fixation device. One or more straps 73 or sleeves may be used to hold the antenna 70 in place during testing, such as by wrapping around a portion of the wearer's body. Once the antenna 70 is in place at 112 and secured to the wearer's body, the portable computing device 72 may receive an indication at 114 that the patient/user wishes to begin testing and begin collecting strain data. The indication 114 may be received via the input device 90 and may include, for example, a physical or virtual button press.
Once an indication of start has been received at 114, the processor 80 may energize (at 116) the antenna 70 via the power transmission circuit 78, which in turn may energize and/or activate the sensors 52, 54. After this, the processor 80 may examine the presence and/or intensity of the data signals returned from each sensor 52, 54 to determine if the device is operational and properly positioned (at 118). If the signal-to-noise ratio is too low (as shown generally at 94 in fig. 5), or if the sensor returns an unexpected reading, the processor 80 may instruct the user to reposition the antenna or seek further support. If the sensor is working well and returns a sufficient signal, the processor 80 may then instruct the user via the display 88 as to how to position their body (at 120). For example, as shown at 96 in fig. 5, the display 88 may show a picture of a person sitting to indicate that the patient should be in a sitting position. The position may be confirmed automatically, for example, by expiration of a countdown timer, user actuation of a button confirming the gesture, or by orientation data collected from an accelerometer or inertial measurement unit disposed on the antenna 70.
Once the user's location has been verified (directly or indirectly), the processor 80 may receive measurement data from the load sensors 52, 54 via the antenna 70 and the communication circuit 76 (at 122). After receipt, the data may optionally be filtered or smoothed (at 124) by the portable computing device 72 to remove communication or measurement noise, error harmonics, and the like. Exemplary filtering techniques may employ the use of low-pass or band-pass filtering techniques and/or data averaging techniques to remove noise within the signal. Additional techniques may include various clipping or sampling strategies operable to isolate a subset of the total received signal having a minimum average or total variance (e.g., root Mean Square (RMS) variance).
Once any on-board data processing is complete (if any such processing is required), the processor 80 may package (at 126) the strain data (in raw and/or filtered/clipped form) from the load sensors 52, 54 along with a unique identifier corresponding to at least one of the identity of the subject or the identity of the implanted smart fixture 40 or the strain sensor mounted thereon. Packaging such data may include generating a digital file in memory that includes sensor data in separate form along with header or metadata information including date/time of reading, device data, environmental data, and/or subject/device identification data. The packaged data/data file may then be transmitted (at 128) via the wireless communication network 28 to the data server 20, where it may then be aggregated and/or recorded (at 132) in conjunction with the unique patient identifier.
The present system may be operably configured to interpret the acquired strain data to determine (at 130) the relative amount of support provided by the bone plate due to the fracture using the different readings between the primary load sensor 52 and the reference load sensor 54. In practice, such analysis may be performed using the processor 80 or by the data server 20. If the analysis is performed by the device processor 80, the results of the analysis will be packaged along with the filtered data or raw data and unique identifier prior to transmission of the information.
In one configuration, the relative amount of support provided by the bone plate may be expressed as a ratio of the strain sensed by the primary load sensor 52 to the strain sensed by the reference load sensor. As the bone heals, this value may be expected to decrease toward 1.0 (taking into account different biomechanical dynamics, where strain may be non-uniform over the length of the bone). A ratio greater than 1.0 will indicate that the bone plate carries a greater amount of load across the fracture than at points distant from the fracture.
In some embodiments, the processor 80 may also normalize the measurements or ratios (e.g., load bearing ratios) acquired during the load bearing pose using the measurements or ratios acquired at no load (e.g., no load ratio). For example, when monitoring a fracture in the femur, a load bearing posture may involve the patient standing upright, whereas an unloaded posture may involve the patient sitting. To achieve this, the method 110 may repeat the instruction/measurement steps (generally at 120-124) while instructing the patient via the display 88 to position themselves at different body locations (shown graphically at 120b in fig. 6 and at 98 in fig. 5). In one configuration, the first proposed body location would be a reference location with substantially no load on the fracture. The second location may then be where a load is applied to the fracture.
In one configuration, the normalization mentioned above may simply involve calculating the ratio of the main strain to the reference strain as the ratio of strain changes. In other words, the system may calculate delta strain delta at the fracture from the unloaded to the load-bearing position and then divide that value by a similarly calculated delta strain delta at the reference location (i.e., from the unloaded to the load-bearing position). This normalization may remove ratio anomalies that may be caused by different baseline readings between sensors. In one configuration, such as generally shown at 98 in fig. 5, when a load bearing posture is indicated, the processor 80 may compare the strain from the reference sensor 54 in the load bearing posture to the strain from the sensor in the no-load posture.
To ensure that sufficient load is applied to the bone to achieve meaningful data points, the processor 80 may monitor the absolute strain and/or delta strain at the fracture to ensure that it is above a predetermined threshold when in the indicated load bearing pose. If the strain is below the threshold, the processor 80 may instruct the wearer to apply a greater load to the fractured bone (such as generally indicated at 98 in FIG. 5). If the ratio or difference is above a threshold, the reading may be recorded with a confidence that the bone in the load bearing pose is bearing a sufficient amount of load so that the result is meaningful.
In other embodiments, the portable computing device 72 may instead instruct the patient (at 120) to engage in some dynamic movement, rather than making measurements during static loading conditions. For example, the portable computing device 72 may instruct the patient to walk, perform some stretching, or perform other functional activities, such as standing from a seated position, climbing stairs, and so forth. In this configuration, rather than simply filtering and/or averaging the received strain readings to obtain a single static strain value, the processor 80 may examine the strain readings over time to identify peak loads throughout the functional activity. These peak load values/ratios may then be normalized for the identified minimum load value/ratio, rather than requiring discrete load bearing and no load positions.
Once the support ratio is obtained, this value can be similarly recorded in conjunction with the subject's identifier. In one configuration, each patient may have a plurality of data points associated with its unique patient identifier. Each data point may represent test results collected at a different time point. Fig. 7 schematically illustrates a plurality of patient data points 140, each data point representing a load ratio 142 acquired over time 144. From these multiple data points 140, a trend line 146 may be constructed that represents the progress of the patient's healing over time, as shown in fig. 7.
Upon receiving a request from a user or medical professional 32 (at 134 in fig. 6), the data server 20 may visually represent aggregated patient data through a hosted user interface/physician interface 34 such as that shown in fig. 8. In one configuration, physician interface 34 may be a web-based display that graphically illustrates the healing progress of one or more patients 148, for example, by displaying collected data points 140 and/or trend lines 146 over time 142. In one configuration, the physician interface 34 may include a diagrammatical screen such as that shown in fig. 8, which enables a physician to quickly scan the progress and compliance of a plurality of patients, each using the present system and periodically transmitting their respective patient data 24 to the data server 20. Selecting either patient may transition physician interface 34 from the overview screen to a more detailed graphical display of the trends of the selected patient, as shown in fig. 7.
In one configuration, as also shown in fig. 7, the data server 20 may calculate and display a patient-specific trajectory range 150 within which the actual trend line 146 of the patient is expected to fall over time. In one configuration, the patient-specific trajectory scope 150 may be a statistical evaluation based on one or more qualitative and/or quantitative attributes/metrics extracted from the patient's medical records or otherwise entered into the data server 20. These characteristics may include factors such as: the nature and location of the fracture, the subject's height, weight, age, sex, metabolic characteristics, blood pressure, past conditions, complex risk factors/complications 152 (shown in fig. 8), or other such factors that may affect healing. In some embodiments, the trajectory range 150 may also be affected by empirical data obtained from previous patients. For example, the data server 20 may maintain a machine learning model (e.g., a supervised or unsupervised learning model) in which empirical evidence obtained from previous patients is used to improve the predictive accuracy of models of future patients. The patient-specific trajectory range 150 may include a predicted trajectory 154 along with one or more confidence intervals 156 that diverge over time. In one configuration, the patient-specific trajectory range 150 may be a static trajectory range 150 that is calculated from the day the bone is fixed (i.e., day 0) and is not updated. By not continually improving the model, the medical professional can understand whether the patient heals as expected, or whether there are unpredictable complications that need to be addressed.
In some implementations, data server 20 may further attempt to extrapolate the trajectory at each step (i.e., where the most recent data point is always 0 days and the previous trend line is an additional input into the model). The prospective track 158 may provide advance notice to the healthcare professional if the trend of the curve may be of later concern. For example, the prospective trajectory 158 in fig. 7 is predicting a slow healing progression for the next 1-2 weeks, which may be outside the expected boundary. Such predictions may alert the physician that something may complicate the progress of healing and may require further investigation. Further, in one configuration, the data server 20 may provide an alert via the physician interface 34 if one of the data points or prospective healing trajectories is outside of the confidence interval. In this way, the more frequent monitoring provided by the present system, along with enhanced data visualization and predictive analysis, may lead to a more comprehensive understanding of how well healing is relative to a reasonably expected patient. This enhanced understanding may enable the physician to intervene at an earlier stage if complications begin to occur. Likewise, this data may also be used to provide guidance regarding recommended physiotherapy treatments and recommended overall patient activity levels.
In one configuration, in addition to being displayed to the physician via the managed interface 34, the recorded patient data points 140, the patient-specific trajectory range 150, the prospective trajectory 158, and/or one or more qualitative summaries may be displayed to the patient via the display 88. In this case, the healing process may be gamified, for example, by celebrating or providing a virtual reward when a certain milestone is reached. Likewise, the portable computing device may communicate prompts or behavioral advice automatically or under remote guidance/input from the physician to help the patient maintain compliance with the prescribed course of therapy.
Fig. 9 schematically illustrates one way of attaching the external wireless reader 42 and/or antenna 70 to the body of the user, and more specifically to the upper thigh, as would be required for a femoral fracture. In such applications, attachment to the body presents challenges because the thickness of the thigh muscle varies based on the posture of the patient. For example, when a patient changes from sitting to standing, their thigh circumference decreases significantly. If not considered, this decrease in leg circumference may cause the external wireless reader 42 to slide downward from its intended location. To prevent such sliding, in one embodiment, the external wireless reader 42 may include one or more elastic bands 160 configured to be secured around the circumference of the patient's body. These elastic bands 160 preferably achieve a tension fit such that they elastically stretch around the patient's limb while exerting a compressive force on the patient's skin. In some embodiments, the external wireless reader 42 may also include one or more brackets 162 configured to be secured around the joints of the fractured bone. For example, in fractures of the femur, the external wireless reader 42 may include a knee brace 164 configured to extend around the patient's knee. The antenna 70 may then be rigidly positioned relative to the bracket 162. This design may be advantageous because the circumference of the joint does not vary significantly based on pose, and similarly, the position of the fracture relative to the joint remains constant. This design will not rely solely on contracting the elastic band to maintain positioning, where reliance on only the elastic band may prove uncomfortable for some patients. In alternative embodiments, a hip brace or strap may be used in place of the knee brace 162.
The present technique represents an advance in the ability of physicians to more actively monitor the healing progress of internal fixation fractures. Using this increased quantitative monitoring, which is particularly suited for telemonitoring/telemedicine, a physician may have a more complete picture of how bones ossify than is available in current practice. With this information, the physician can more actively customize the physical therapy regimen, suggest acceptable activity levels or diets to the patient, or even take active intervention steps if desired. Because bone healing is generally slow, the device of the present invention may not need to be continuously worn. In contrast, the external wireless reader 42 may be more similar to a blood pressure cuff, in that it only needs to be worn during testing (it may only need to be worn several times per week).
Other aspects and advantages of the present technology are provided in the following clauses:
clause 1. A patient monitoring system for monitoring ossification of an internal fixation fracture in a bone of a subject, the system comprising: an implantable fixation device operable to attach to the bone, the fixation device comprising: a bone plate configured to be secured to the bone on an opposite side of the fracture; a primary load sensor disposed at a first location on the bone plate, the first location operable to be positioned directly adjacent to the fracture, the primary load sensor comprising: a first strain sensor operable to monitor an amount of strain (primary strain) at the first location in the bone plate; and communication circuitry operable to transmit a first wireless signal indicative of a main strain amount; a reference load sensor disposed on the bone plate at a second location spaced apart from the first location, the reference load sensor comprising: a second strain sensor operable to monitor an amount of strain (reference strain) at the second location in the bone plate; and a communication circuit operable to transmit a second wireless signal indicative of a reference strain amount; an external wireless reader comprising an antenna, a processor, and a wireless communication radio, wherein the processor is configured to: receiving the first wireless signal and the second wireless signal via the antenna; transmitting a signal over a wireless communication network to a data server using the wireless communication radio, the signal indicating the primary strain amount, the reference strain amount, and the system further comprising a unique identifier corresponding to at least one of the subject or the implantable fixture.
Clause 2 the patient monitoring system of clause 1, further comprising the data server in digital communication with the external wireless reader; wherein at least one of the processor or the data server is configured to: determining an amount of relative support provided by the bone plate due to the fracture using the received indication of the primary strain and the received indication of the reference strain; and storing the determined relative support amount in a non-transitory memory in communication with at least one of the processor or the data server.
Clause 3 the patient monitoring system of clause 2, wherein the processor or data server is configured to determine the relative amount of support provided by the bone plate by calculating a ratio of the primary strain to the reference strain.
Clause 4 the patient monitoring system of clause 3, wherein the processor is further configured to: prompting the subject to position the bone in a first, non-load bearing position and to separately position the bone in a second, load bearing position; determining a main strain amount in each of the first and second load-bearing positions; determining a reference strain amount in each of the first and second load-bearing positions; and wherein at least one of the processor or data server is configured to determine the amount of relative support provided by the bone plate by calculating a ratio of a primary strain differential between the no-load pose and the load-bearing pose to a reference strain differential between the no-load pose and the load-bearing pose.
Clause 5 the patient monitoring system of clause 4, wherein the external wireless reader further comprises a display, and wherein the processor is configured to prompt the subject via the display to position the bone in the first, non-load bearing position and separately in the second, load bearing position.
Clause 6 the patient monitoring system of clause 5, wherein the processor is configured to: if the primary strain in the load bearing posture is less than a predetermined minimum threshold amount of strain, prompting the subject via the display to apply additional load to the bone.
Clause 7 the patient monitoring system of any of clauses 4-6, wherein at least one of the processor or data server is configured to determine the amount of relative support provided by the bone plate only when the primary strain in the load bearing posture exceeds a predetermined minimum threshold strain amount.
Clause 9 the patient monitoring system of clause 8, wherein the external wireless reader comprises a wearable component in wired communication with a display device via a tether; and wherein the wearable component comprises an antenna disposed in a carrier having at least one strap configured to extend around a portion of the subject.
Clause 11 the patient monitoring system of any of clauses 9-10, wherein the fabric carrier is further secured to a bracket operable to extend around a joint of the subject.
The patient monitoring system of any one of clauses 1-11, wherein the antenna has a length, and wherein the length of the antenna is greater than the spacing between the first location and the second location.
Clause 13. A method of monitoring fracture ossification from a plurality of subjects, the method comprising: receiving, via a wireless communication network, a plurality of data sets from a plurality of subjects, each data set representing a plurality of strain measurements obtained from a smart fixation device secured to a bone of a subject across a fracture, the plurality of strain measurements including at least a first strain measurement indicative of an amount of load carried by the fixation device across the fracture (primary strain) and at least a second strain measurement indicative of an amount of load carried by the fixation device at dense bone (reference strain); a ratio of the main strain amount to the reference strain amount for each of the plurality of data sets is calculated. Storing each dataset and each calculated ratio in non-volatile memory in combination with a date and time of the strain measurement and with a patient identifier representing a source of the measurement; and providing a physician interface to graphically illustrate the change in ratio from each of the plurality of different subjects over time.
Clause 15 the method of clause 14, further comprising: calculating a prospective healing trajectory for each subject, the trajectory extending forward in time from a most recently acquired dataset for the subject; and superimposing the prospective healing track on the graphical representation of the predicted patient-specific healing track.
Clause 16 the method of clause 15, further comprising: if one of the dataset or the prospective healing trajectory is outside the confidence interval, an alert is provided via the physician interface.
Clause 17. A method of collecting ossification data from an implantable smart fixation device disposed within a subject, the method comprising: energizing an external antenna to generate an alternating magnetic field and inductively energizing a plurality of load sensors, the load sensors being disposed in contact with a bone plate, the bone plate being secured to bone across a fracture; receiving wireless data signals from each of the plurality of load sensors via the external antenna, the wireless data signals being indicative of an amount of strain experienced by the bone plate; identifying a representative strain value from each wireless data signal; the relative amount of load carried by the bone plate across the fracture is determined by dividing a first strain value indicative of the amount of strain experienced by the bone plate at the fracture by a second strain value indicative of the amount of strain experienced by the bone plate away from the fracture.
Clause 18 the method of clause 17, further comprising: prompting the subject, via an electronic display, to position the bone or the subject's body in a first unloaded pose; and prompting the subject, via the electronic display, to position the bone or the subject's body in a second load bearing posture, wherein the bone plate is subjected to at least a predetermined minimum amount of strain in the load bearing posture; and wherein each of the first strain value and the second strain value comprises a difference between the amounts of strain measured in the load-bearing and no-load positions.
Clause 19 the method of clause 18, further comprising providing a warning to the subject if the amount of strain in the load bearing pose is less than the predetermined minimum amount of strain.
Benefits, other advantages, and solutions to problems have been described with regard to specific embodiments. The benefits, advantages, solutions to problems, and any element(s) that may cause any benefit, advantage, or solution to occur or become more pronounced, however, are not to be construed as a critical, required, or essential feature or element of any or all the claims unless such benefits, advantages, solutions, and elements are explicitly described as such in such claims.
Furthermore, if embodiments and/or limitations: (1) are not explicitly claimed in the claims; (2) In an equivalent manner, as obvious elements and/or limitations in the claims are or potentially are equivalents of the disclosed embodiments and limitations herein are not dedicated to the public under the doctrine of equivalents.
Additional embodiments of external wireless readers are provided in the appendix filed herewith.
Claims (19)
1. A patient monitoring system for monitoring ossification of an internal fixation fracture in a bone of a subject, the system comprising:
An implantable fixation device operable to attach to the bone, the fixation device comprising:
a bone plate configured to be secured to the bone on an opposite side of the fracture;
a primary load sensor disposed at a first location on the bone plate, the first location operable to be positioned directly adjacent to the fracture, the primary load sensor comprising: a first strain sensor operable to monitor an amount of strain (primary strain) at the first location in the bone plate; and communication circuitry operable to transmit a first wireless signal indicative of a main strain amount;
a reference load sensor disposed on the bone plate at a second location spaced apart from the first location, the reference load sensor comprising: a second strain sensor operable to monitor an amount of strain (reference strain) at the second location in the bone plate; and a communication circuit operable to transmit a second wireless signal indicative of a reference strain amount;
An external wireless reader comprising an antenna, a processor, and a wireless communication radio, wherein the processor is configured to:
receiving the first wireless signal and the second wireless signal via the antenna;
transmitting a signal over a wireless communication network to a data server using the wireless communication radio, the signal indicating the primary strain amount, the reference strain amount, and further comprising a unique identifier corresponding to at least one of the subject or the implantable fixture.
2. The patient monitoring system of claim 1, further comprising the data server in digital communication with the external wireless reader;
wherein at least one of the processor or the data server is configured to:
determining an amount of relative support provided by the bone plate due to the fracture using the received indication of the primary strain and the received indication of the reference strain; and
the determined relative amount of support is stored in a non-transitory memory in communication with at least one of the processor or the data server.
3. The patient monitoring system of claim 2, wherein the processor or data server is configured to determine the relative amount of support provided by the bone plate by calculating a ratio of the primary strain to the reference strain.
4. The patient monitoring system of claim 3,
wherein the processor is further configured to:
prompting the subject to position the bone in a first, non-load bearing position and to separately position the bone in a second, load bearing position;
determining a main strain amount in each of the first and second load-bearing positions;
determining a reference strain amount in each of the first and second load-bearing positions; and is also provided with
Wherein at least one of the processor or data server is configured to determine the relative amount of support provided by the bone plate by calculating a ratio of a primary strain differential between the no-load pose and the load-bearing pose to a reference strain differential between the no-load pose and the load-bearing pose.
5. The patient monitoring system of claim 4, wherein the external wireless reader further comprises a display, and wherein the processor is configured to prompt the subject via the display to position the bone in the first, unloaded posture and separately in the second, load-bearing posture.
6. The patient monitoring system of claim 5, wherein the processor is configured to: if the primary strain in the load bearing posture is less than a predetermined minimum threshold amount of strain, prompting the subject via the display to apply additional load to the bone.
7. The patient monitoring system of claim 4, wherein at least one of the processor or data server is configured to determine the relative amount of support provided by the bone plate only when the primary strain in the load bearing posture exceeds a predetermined minimum threshold strain amount.
8. The patient monitoring system of claim 1, wherein the external wireless reader further comprises an inductive charging circuit operable to power each of the primary and reference load sensors via a magnetic field emitted from the antenna.
9. The patient monitoring system of claim 8, wherein the external wireless reader comprises a wearable component in wired communication with a display device via a tether; and is also provided with
Wherein the wearable component includes an antenna disposed in a carrier having at least one strap configured to extend around a portion of the subject.
10. The patient monitoring system of claim 9, wherein the wearable component further comprises the processor.
11. The patient monitoring system of claim 9, wherein the fabric carrier is further secured to a bracket operable to extend around a joint of the subject.
12. The patient monitoring system of claim 1, wherein the antenna has a length, and wherein the length of the antenna is greater than a spacing between the first location and the second location.
13. A method of monitoring fracture ossification from a plurality of subjects, the method comprising:
receiving, via a wireless communication network, a plurality of data sets from a plurality of subjects, each data set representing a plurality of strain measurements obtained from a smart fixation device secured to a bone of a subject across a fracture, the plurality of strain measurements including at least a first strain measurement indicative of an amount of load carried by the fixation device across the fracture (primary strain) and at least a second strain measurement indicative of an amount of load carried by the fixation device at dense bone (reference strain);
A ratio of the main strain amount to the reference strain amount for each of the plurality of data sets is calculated.
Storing each dataset and each calculated ratio in non-volatile memory in combination with a date and time of the strain measurement and with a patient identifier representing a source of the measurement; and
a physician interface is provided to graphically illustrate the change in ratio from each of a plurality of different subjects over time.
14. The method of claim 13, further comprising maintaining a machine learning predictive model that generates a predicted patient-specific healing trajectory for each subject, the patient-specific healing trajectory including a predicted trajectory and a confidence interval that represents a likely healing progression process that begins at bone fixation, the method further comprising superimposing a plurality of data sets of a subject on a graphical representation of the predicted patient-specific healing trajectory within the physician interface; and is also provided with
Wherein the machine learning predictive model is improved using at least a subset of the received data set and a plurality of secondary factors including at least two of: the nature and location of the fracture, the subject's height, weight, age, sex, metabolic characteristics, blood pressure, past conditions, complex risk factors, or complications.
15. The method of claim 14, further comprising: calculating a prospective healing trajectory for each subject, the trajectory extending forward in time from a most recently acquired dataset of the subject; and
the prospective healing track is superimposed on the graphical representation of the predicted patient-specific healing track.
16. The method of claim 15, further comprising: if one of the dataset or the prospective healing trajectory is outside the confidence interval, an alert is provided via the physician interface.
17. A method of collecting ossification data from an implantable intelligent fixation device disposed within a subject, the method comprising:
energizing an external antenna to generate an alternating magnetic field and inductively energizing a plurality of load sensors disposed in contact with a bone plate secured to the bone across the fracture;
receiving wireless data signals from each of the plurality of load sensors via the extracorporeal antenna, the wireless data signals being indicative of an amount of strain experienced by the bone plate;
identifying a representative strain value from each wireless data signal;
the relative amount of load carried by the bone plate across the fracture is determined by dividing a first strain value indicative of the amount of strain experienced by the bone plate at the fracture by a second strain value indicative of the amount of strain experienced by the bone plate away from the fracture.
18. The method of claim 17, further comprising:
prompting the subject, via an electronic display, to position the bone or the subject's body in a first unloaded pose; and
prompting, via the electronic display, the subject to position the bone or the subject's body in a second load bearing posture, wherein the bone plate is subjected to at least a predetermined minimum amount of strain in the load bearing posture; and is also provided with
Wherein each of the first strain value and the second strain value comprises a difference between the amounts of strain measured in the load-bearing and no-load positions.
19. The method of claim 18, further comprising providing a warning to the subject if the amount of strain in the load bearing posture is less than the predetermined minimum amount of strain.
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CN117717319A (en) * | 2023-12-18 | 2024-03-19 | 北京航空航天大学 | System and method for measuring fracture rigidity after lower limb intramedullary nail operation based on RFID |
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